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	# Copyright 2018 the HuggingFace Inc. team.
	#
	# Licensed under the Apache License, Version 2.0 (the "License");
	# you may not use this file except in compliance with the License.
	# You may obtain a copy of the License at
	#
	# http://www.apache.org/licenses/LICENSE-2.0
	#
	# Unless required by applicable law or agreed to in writing, software
	# distributed under the License is distributed on an "AS IS" BASIS,
	# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	# See the License for the specific language governing permissions and
	# limitations under the License.

	import copy
	import unittest

	import numpy as np

	from transformers.data.data_collator import default_data_collator
	from transformers.testing_utils import require_accelerate, require_torch
	from transformers.trainer_utils import RemoveColumnsCollator, find_executable_batch_size
	from transformers.utils import is_torch_available


	if is_torch_available():
	import torch
	from torch import nn
	from torch.utils.data import IterableDataset

	from transformers.modeling_outputs import SequenceClassifierOutput
	from transformers.tokenization_utils_base import BatchEncoding
	from transformers.trainer_pt_utils import (
	DistributedLengthGroupedSampler,
	DistributedSamplerWithLoop,
	DistributedTensorGatherer,
	EvalLoopContainer,
	IterableDatasetShard,
	LabelSmoother,
	LengthGroupedSampler,
	SequentialDistributedSampler,
	ShardSampler,
	get_parameter_names,
	numpy_pad_and_concatenate,
	torch_pad_and_concatenate,
	)

	class TstLayer(nn.Module):
	def __init__(self, hidden_size):
	super().__init__()
	self.linear1 = nn.Linear(hidden_size, hidden_size)
	self.ln1 = nn.LayerNorm(hidden_size)
	self.linear2 = nn.Linear(hidden_size, hidden_size)
	self.ln2 = nn.LayerNorm(hidden_size)
	self.bias = nn.Parameter(torch.zeros(hidden_size))

	def forward(self, x):
	h = self.ln1(nn.functional.relu(self.linear1(x)))
	h = nn.functional.relu(self.linear2(x))
	return self.ln2(x + h + self.bias)

	class RandomIterableDataset(IterableDataset):
	# For testing, an iterable dataset of random length
	def __init__(self, p_stop=0.01, max_length=1000):
	self.p_stop = p_stop
	self.max_length = max_length
	self.generator = torch.Generator()

	def __iter__(self):
	count = 0
	stop = False
	while not stop and count < self.max_length:
	yield count
	count += 1
	number = torch.rand(1, generator=self.generator).item()
	stop = number < self.p_stop


	@require_torch
	class TrainerUtilsTest(unittest.TestCase):
	def test_distributed_tensor_gatherer(self):
	# Simulate a result with a dataset of size 21, 4 processes and chunks of lengths 2, 3, 1
	world_size = 4
	num_samples = 21
	input_indices = [
	[0, 1, 6, 7, 12, 13, 18, 19],
	[2, 3, 4, 8, 9, 10, 14, 15, 16, 20, 0, 1],
	[5, 11, 17, 2],
	]

	predictions = np.random.normal(size=(num_samples, 13))
	gatherer = DistributedTensorGatherer(world_size=world_size, num_samples=num_samples)
	for indices in input_indices:
	gatherer.add_arrays(predictions[indices])
	result = gatherer.finalize()
	self.assertTrue(np.array_equal(result, predictions))

	# With nested tensors
	gatherer = DistributedTensorGatherer(world_size=world_size, num_samples=num_samples)
	for indices in input_indices:
	gatherer.add_arrays([predictions[indices], [predictions[indices], predictions[indices]]])
	result = gatherer.finalize()
	self.assertTrue(isinstance(result, list))
	self.assertEqual(len(result), 2)
	self.assertTrue(isinstance(result[1], list))
	self.assertEqual(len(result[1]), 2)
	self.assertTrue(np.array_equal(result[0], predictions))
	self.assertTrue(np.array_equal(result[1][0], predictions))
	self.assertTrue(np.array_equal(result[1][1], predictions))

	def test_distributed_tensor_gatherer_different_shapes(self):
	# Simulate a result with a dataset of size 21, 4 processes and chunks of lengths 2, 3, 1
	world_size = 4
	num_samples = 21
	input_indices = [
	[0, 1, 6, 7, 12, 13, 18, 19],
	[2, 3, 4, 8, 9, 10, 14, 15, 16, 20, 0, 1],
	[5, 11, 17, 2],
	]
	sequence_lengths = [8, 10, 13]

	predictions = np.random.normal(size=(num_samples, 13))
	gatherer = DistributedTensorGatherer(world_size=world_size, num_samples=num_samples)
	for indices, seq_length in zip(input_indices, sequence_lengths):
	gatherer.add_arrays(predictions[indices, :seq_length])
	result = gatherer.finalize()

	# Remove the extra samples added at the end for a round multiple of num processes.
	actual_indices = [input_indices[0], input_indices[1][:-2], input_indices[2][:-1]]
	for indices, seq_length in zip(actual_indices, sequence_lengths):
	self.assertTrue(np.array_equal(result[indices, :seq_length], predictions[indices, :seq_length]))

	# With nested tensors
	predictions = np.random.normal(size=(num_samples, 13))
	gatherer = DistributedTensorGatherer(world_size=world_size, num_samples=num_samples)
	for indices, seq_length in zip(input_indices, sequence_lengths):
	gatherer.add_arrays([predictions[indices, :seq_length], predictions[indices]])
	result = gatherer.finalize()

	for indices, seq_length in zip(actual_indices, sequence_lengths):
	self.assertTrue(np.array_equal(result[0][indices, :seq_length], predictions[indices, :seq_length]))
	self.assertTrue(np.array_equal(result[1], predictions))

	# Check if works if varying seq_length is second
	gatherer = DistributedTensorGatherer(world_size=world_size, num_samples=num_samples)
	for indices, seq_length in zip(input_indices, sequence_lengths):
	gatherer.add_arrays([predictions[indices], predictions[indices, :seq_length]])
	result = gatherer.finalize()

	self.assertTrue(np.array_equal(result[0], predictions))
	for indices, seq_length in zip(actual_indices, sequence_lengths):
	self.assertTrue(np.array_equal(result[1][indices, :seq_length], predictions[indices, :seq_length]))

	def test_label_smoothing(self):
	epsilon = 0.1
	num_labels = 12
	random_logits = torch.randn(4, 5, num_labels)
	random_labels = torch.randint(0, num_labels, (4, 5))
	loss = nn.functional.cross_entropy(random_logits.view(-1, num_labels), random_labels.view(-1))
	model_output = SequenceClassifierOutput(logits=random_logits)
	label_smoothed_loss = LabelSmoother(0.1)(model_output, random_labels)
	log_probs = -nn.functional.log_softmax(random_logits, dim=-1)
	expected_loss = (1 - epsilon) * loss + epsilon * log_probs.mean()
	torch.testing.assert_close(label_smoothed_loss, expected_loss)

	# With a few -100 labels
	random_labels[0, 1] = -100
	random_labels[2, 1] = -100
	random_labels[2, 3] = -100

	loss = nn.functional.cross_entropy(random_logits.view(-1, num_labels), random_labels.view(-1))
	model_output = SequenceClassifierOutput(logits=random_logits)
	label_smoothed_loss = LabelSmoother(0.1)(model_output, random_labels)
	log_probs = -nn.functional.log_softmax(random_logits, dim=-1)
	# Mask the log probs with the -100 labels
	log_probs[0, 1] = 0.0
	log_probs[2, 1] = 0.0
	log_probs[2, 3] = 0.0
	expected_loss = (1 - epsilon) * loss + epsilon * log_probs.sum() / (num_labels * 17)
	torch.testing.assert_close(label_smoothed_loss, expected_loss)

	def test_group_by_length(self):
	# Get some inputs of random lengths
	lengths = torch.randint(0, 25, (100,)).tolist()
	# Put one bigger than the others to check it ends up in first position
	lengths[32] = 50

	indices = list(LengthGroupedSampler(4, lengths=lengths))
	# The biggest element should be first
	self.assertEqual(lengths[indices[0]], 50)
	# The indices should be a permutation of range(100)
	self.assertEqual(sorted(indices), list(range(100)))

	def test_group_by_length_with_dict(self):
	# Get some inputs of random lengths
	data = []
	for _ in range(6):
	input_ids = torch.randint(0, 25, (100,)).tolist()
	data.append({"input_ids": input_ids})
	# Put one bigger than the others to check it ends up in first position
	data[3]["input_ids"] = torch.randint(0, 25, (105,)).tolist()

	indices = list(LengthGroupedSampler(4, dataset=data))
	# The biggest element should be first
	self.assertEqual(len(data[indices[0]]["input_ids"]), 105)
	# The indices should be a permutation of range(6)
	self.assertEqual(sorted(indices), list(range(6)))

	def test_group_by_length_with_batch_encoding(self):
	# Get some inputs of random lengths
	data = []
	for _ in range(6):
	input_ids = torch.randint(0, 25, (100,)).tolist()
	data.append(BatchEncoding({"input_ids": input_ids}))
	# Put one bigger than the others to check it ends up in first position
	data[3]["input_ids"] = torch.randint(0, 25, (105,)).tolist()

	indices = list(LengthGroupedSampler(4, dataset=data))
	# The biggest element should be first
	self.assertEqual(len(data[indices[0]]["input_ids"]), 105)
	# The indices should be a permutation of range(6)
	self.assertEqual(sorted(indices), list(range(6)))

	def test_distributed_length_grouped(self):
	# Get some inputs of random lengths
	lengths = torch.randint(0, 25, (100,)).tolist()
	# Put one bigger than the others to check it ends up in first position
	lengths[32] = 50

	indices_process_0 = list(DistributedLengthGroupedSampler(4, num_replicas=2, rank=0, lengths=lengths))
	indices_process_1 = list(DistributedLengthGroupedSampler(4, num_replicas=2, rank=1, lengths=lengths))
	# The biggest element should be first
	self.assertEqual(lengths[indices_process_0[0]], 50)
	# The indices should be a permutation of range(100)
	self.assertEqual(sorted(indices_process_0 + indices_process_1), list(range(100)))

	def test_get_parameter_names(self):
	model = nn.Sequential(TstLayer(128), nn.ModuleList([TstLayer(128), TstLayer(128)]))
	# fmt: off
	self.assertEqual(
	get_parameter_names(model, [nn.LayerNorm]),
	['0.linear1.weight', '0.linear1.bias', '0.linear2.weight', '0.linear2.bias', '0.bias', '1.0.linear1.weight', '1.0.linear1.bias', '1.0.linear2.weight', '1.0.linear2.bias', '1.0.bias', '1.1.linear1.weight', '1.1.linear1.bias', '1.1.linear2.weight', '1.1.linear2.bias', '1.1.bias']
	)
	# fmt: on

	def test_get_parameter_names_rmsnorm(self):
	class RMSNorm(nn.Module):
	def __init__(self, hidden_size):
	super().__init__()
	self.weight = nn.Parameter(torch.ones(hidden_size))
	self.bias = nn.Parameter(torch.zeros(hidden_size))

	class ModelWithRMSNorm(nn.Module):
	def __init__(self):
	super().__init__()
	self.linear = nn.Linear(128, 128)
	self.rmsnorm = RMSNorm(128)
	self.bias = nn.Parameter(torch.zeros(128))

	model = ModelWithRMSNorm()
	# Test both type-based and name-based filtering
	decay_parameters = get_parameter_names(model, [], ["bias", "rmsnorm"])

	# Parameters that should be in weight decay
	self.assertIn("linear.weight", decay_parameters)

	# Parameters that should NOT be in weight decay
	self.assertNotIn("linear.bias", decay_parameters)
	self.assertNotIn("rmsnorm.weight", decay_parameters)
	self.assertNotIn("rmsnorm.bias", decay_parameters)
	self.assertNotIn("bias", decay_parameters)

	def test_distributed_sampler_with_loop(self):
	batch_size = 16
	for length in [23, 64, 123]:
	dataset = list(range(length))
	shard1 = DistributedSamplerWithLoop(dataset, batch_size, num_replicas=2, rank=0)
	shard2 = DistributedSamplerWithLoop(dataset, batch_size, num_replicas=2, rank=1)

	# Set seeds
	shard1.set_epoch(0)
	shard2.set_epoch(0)

	# Sample
	samples1 = list(shard1)
	samples2 = list(shard2)

	self.assertTrue(len(samples1) % batch_size == 0)
	self.assertTrue(len(samples2) % batch_size == 0)

	total = []
	for sample1, sample2 in zip(samples1, samples2):
	total += [sample1, sample2]

	self.assertEqual(set(total[:length]), set(dataset))
	self.assertEqual(set(total[length:]), set(total[: (len(total) - length)]))

	def test_sequential_distributed_sampler(self):
	batch_size = 16
	for length in [23, 64, 123]:
	dataset = list(range(length))
	shard1 = SequentialDistributedSampler(dataset, num_replicas=2, rank=0)
	shard2 = SequentialDistributedSampler(dataset, num_replicas=2, rank=1)

	# Sample
	samples1 = list(shard1)
	samples2 = list(shard2)

	total = samples1 + samples2

	self.assertListEqual(total[:length], dataset)
	self.assertListEqual(total[length:], dataset[: (len(total) - length)])

	# With a batch_size passed
	shard1 = SequentialDistributedSampler(dataset, num_replicas=2, rank=0, batch_size=batch_size)
	shard2 = SequentialDistributedSampler(dataset, num_replicas=2, rank=1, batch_size=batch_size)

	# Sample
	samples1 = list(shard1)
	samples2 = list(shard2)

	self.assertTrue(len(samples1) % batch_size == 0)
	self.assertTrue(len(samples2) % batch_size == 0)

	total = samples1 + samples2

	self.assertListEqual(total[:length], dataset)
	self.assertListEqual(total[length:], dataset[: (len(total) - length)])

	def check_iterable_dataset_shard(self, dataset, batch_size, drop_last, num_processes=2, epoch=0):
	# Set the seed for the base dataset to get the proper reference.
	dataset.generator.manual_seed(epoch)
	reference = list(dataset)

	shards = [
	IterableDatasetShard(
	dataset, batch_size=batch_size, drop_last=drop_last, num_processes=num_processes, process_index=i
	)
	for i in range(num_processes)
	]
	for shard in shards:
	shard.set_epoch(epoch)
	shard_lists = [list(shard) for shard in shards]

	for shard in shard_lists:
	# All shards have a number of samples that is a round multiple of batch size
	self.assertTrue(len(shard) % batch_size == 0)
	# All shards have the same number of samples
	self.assertEqual(len(shard), len(shard_lists[0]))

	for shard in shards:
	# All shards know the total number of samples
	self.assertEqual(shard.num_examples, len(reference))

	observed = []
	for idx in range(0, len(shard_lists[0]), batch_size):
	for shard in shard_lists:
	observed += shard[idx : idx + batch_size]

	# If drop_last is False we loop through samples at the beginning to have a size that is a round multiple of
	# batch_size
	if not drop_last:
	while len(reference) < len(observed):
	reference += reference
	self.assertListEqual(observed, reference[: len(observed)])

	# Check equivalence between IterableDataset and ShardSampler
	dataset.generator.manual_seed(epoch)
	reference = list(dataset)

	sampler_shards = [
	ShardSampler(
	reference, batch_size=batch_size, drop_last=drop_last, num_processes=num_processes, process_index=i
	)
	for i in range(num_processes)
	]
	for shard, sampler_shard in zip(shard_lists, sampler_shards):
	self.assertListEqual(shard, list(sampler_shard))

	def test_iterable_dataset_shard(self):
	dataset = RandomIterableDataset()

	self.check_iterable_dataset_shard(dataset, 4, drop_last=True, num_processes=2, epoch=0)
	self.check_iterable_dataset_shard(dataset, 4, drop_last=False, num_processes=2, epoch=0)

	self.check_iterable_dataset_shard(dataset, 4, drop_last=True, num_processes=3, epoch=42)
	self.check_iterable_dataset_shard(dataset, 4, drop_last=False, num_processes=3, epoch=42)

	def test_iterable_dataset_shard_with_length(self):
	sampler_shards = [
	IterableDatasetShard(list(range(100)), batch_size=4, drop_last=True, num_processes=2, process_index=i)
	for i in range(2)
	]

	# Build expected shards: each process will have batches of size 4 until there is not enough elements to
	# form two full batches (so we stop at 96 = (100 // (4 * 2)) * 4)
	expected_shards = [[], []]
	current_shard = 0
	for i in range(0, 96, 4):
	expected_shards[current_shard].extend(list(range(i, i + 4)))
	current_shard = 1 - current_shard

	self.assertListEqual([list(shard) for shard in sampler_shards], expected_shards)
	self.assertListEqual([len(shard) for shard in sampler_shards], [len(shard) for shard in expected_shards])

	sampler_shards = [
	IterableDatasetShard(list(range(100)), batch_size=4, drop_last=False, num_processes=2, process_index=i)
	for i in range(2)
	]
	# When drop_last=False, we get two last full batches by looping back to the beginning.
	expected_shards[0].extend(list(range(96, 100)))
	expected_shards[1].extend(list(range(0, 4)))

	self.assertListEqual([list(shard) for shard in sampler_shards], expected_shards)
	self.assertListEqual([len(shard) for shard in sampler_shards], [len(shard) for shard in expected_shards])

	def check_shard_sampler(self, dataset, batch_size, drop_last, num_processes=2):
	shards = [
	ShardSampler(
	dataset, batch_size=batch_size, drop_last=drop_last, num_processes=num_processes, process_index=i
	)
	for i in range(num_processes)
	]
	shard_lists = [list(shard) for shard in shards]

	for shard in shard_lists:
	# All shards have a number of samples that is a round multiple of batch size
	self.assertTrue(len(shard) % batch_size == 0)
	# All shards have the same number of samples
	self.assertEqual(len(shard), len(shard_lists[0]))

	observed = []
	for idx in range(0, len(shard_lists[0]), batch_size):
	for shard in shard_lists:
	observed += shard[idx : idx + batch_size]

	# If drop_last is False we loop through samples at the beginning to have a size that is a round multiple of
	# batch_size
	reference = copy.copy(dataset)
	if not drop_last:
	while len(reference) < len(observed):
	reference += reference
	self.assertListEqual(observed, reference[: len(observed)])

	def test_shard_sampler(self):
	for n_elements in [64, 123]:
	dataset = list(range(n_elements))

	self.check_shard_sampler(dataset, 4, drop_last=True, num_processes=2)
	self.check_shard_sampler(dataset, 4, drop_last=False, num_processes=2)

	self.check_shard_sampler(dataset, 4, drop_last=True, num_processes=3)
	self.check_shard_sampler(dataset, 4, drop_last=False, num_processes=3)

	@require_accelerate
	def test_executable_batch_size(self):
	batch_sizes = []

	@find_executable_batch_size(starting_batch_size=64, auto_find_batch_size=True)
	def mock_training_loop_function(batch_size):
	nonlocal batch_sizes
	batch_sizes.append(batch_size)
	if batch_size > 16:
	raise RuntimeError("CUDA out of memory.")

	mock_training_loop_function()
	self.assertEqual(batch_sizes, [64, 32, 16])

	@require_accelerate
	def test_executable_batch_size_no_search(self):
	batch_sizes = []

	@find_executable_batch_size(starting_batch_size=64, auto_find_batch_size=False)
	def mock_training_loop_function(batch_size):
	nonlocal batch_sizes
	batch_sizes.append(batch_size)

	mock_training_loop_function()
	self.assertEqual(batch_sizes, [64])

	@require_accelerate
	def test_executable_batch_size_with_error(self):
	@find_executable_batch_size(starting_batch_size=64, auto_find_batch_size=False)
	def mock_training_loop_function(batch_size):
	raise RuntimeError("CUDA out of memory.")

	with self.assertRaises(RuntimeError) as cm:
	mock_training_loop_function()
	self.assertEqual("CUDA out of memory", cm.args[0])

	def test_pad_and_concatenate_with_1d(self):
	"""Tests whether pad_and_concatenate works with scalars."""
	array1 = 1.0
	array2 = 2.0
	result = numpy_pad_and_concatenate(array1, array2)
	self.assertTrue(np.array_equal(np.array([1.0, 2.0]), result))

	tensor1 = torch.tensor(1.0)
	tensor2 = torch.tensor(2.0)
	result = torch_pad_and_concatenate(tensor1, tensor2)
	self.assertTrue(torch.equal(result, torch.Tensor([1.0, 2.0])))

	def test_remove_columns_collator(self):
	class MockLogger:
	def __init__(self) -> None:
	self.called = 0

	def info(self, msg):
	self.called += 1
	self.last_msg = msg

	data_batch = [
	{"col1": 1, "col2": 2, "col3": 3},
	{"col1": 1, "col2": 2, "col3": 3},
	]
	logger = MockLogger()
	remove_columns_collator = RemoveColumnsCollator(
	default_data_collator, ["col1", "col2"], logger, "model", "training"
	)

	self.assertNotIn("col3", remove_columns_collator(data_batch))
	# check that the logging message is printed out only once
	remove_columns_collator(data_batch)
	remove_columns_collator(data_batch)
	self.assertEqual(logger.called, 1)
	self.assertIn("col3", logger.last_msg)

	def test_eval_loop_container(self):
	batch_1 = [
	torch.ones([8, 5]),
	{"loss": torch.tensor(1.0)},
	(torch.ones([8, 2, 3]), torch.ones([8, 2])),
	]
	batch_2 = [
	torch.ones([4, 5]),
	{"loss": torch.tensor(2.0)},
	(torch.ones([4, 2, 3]), torch.ones([4, 6])),
	]

	concat_container = EvalLoopContainer(do_nested_concat=True, padding_index=-100)
	concat_container.add(batch_1)
	concat_container.add(batch_2)
	concat_container.to_cpu_and_numpy()
	arrays = concat_container.get_arrays()

	# Test two nested batches concatenation
	self.assertIsInstance(arrays, list)
	self.assertEqual(len(arrays), 3)
	self.assertIsInstance(arrays[0], np.ndarray)
	self.assertEqual(arrays[0].shape, (12, 5))
	self.assertIsInstance(arrays[1], dict)
	self.assertIsInstance(arrays[1]["loss"], np.ndarray)
	self.assertEqual(arrays[1]["loss"].shape, (2,))
	self.assertTrue(np.allclose(arrays[1]["loss"], np.array([1.0, 2.0])))
	self.assertIsInstance(arrays[2], tuple)
	self.assertEqual(len(arrays[2]), 2)
	self.assertEqual(arrays[2][0].shape, (12, 2, 3))
	self.assertEqual(arrays[2][1].shape, (12, 6))
	# check that first batch padded with padding index -100 after concatenation
	self.assertEqual(arrays[2][1][0][2], -100)

	# Test two batches with no concatenation
	list_container = EvalLoopContainer(do_nested_concat=False)
	list_container.add(batch_1)
	list_container.add(batch_2)
	list_container.to_cpu_and_numpy()
	arrays = list_container.get_arrays()

	self.assertEqual(len(arrays), 2)
	self.assertIsInstance(arrays, list)
	np_batch_1, np_batch_2 = arrays

	self.assertIsInstance(np_batch_1, list)
	self.assertEqual(len(np_batch_1), 3)
	self.assertIsInstance(np_batch_1[0], np.ndarray)
	self.assertIsInstance(np_batch_1[1], dict)
	self.assertIsInstance(np_batch_1[2], tuple)
	self.assertEqual(np_batch_1[0].shape, (8, 5))
	self.assertEqual(np_batch_1[1]["loss"].shape, ())
	self.assertEqual(np_batch_1[2][0].shape, (8, 2, 3))
	self.assertEqual(np_batch_1[2][1].shape, (8, 2))

	self.assertIsInstance(np_batch_2, list)
	self.assertEqual(len(np_batch_2), 3)
	self.assertIsInstance(np_batch_2[0], np.ndarray)
	self.assertIsInstance(np_batch_2[1], dict)
	self.assertIsInstance(np_batch_2[2], tuple)
	self.assertEqual(np_batch_2[0].shape, (4, 5))
	self.assertEqual(np_batch_2[1]["loss"].shape, ())
	self.assertEqual(np_batch_2[2][0].shape, (4, 2, 3))
	self.assertEqual(np_batch_2[2][1].shape, (4, 6))

	# Test no batches
	none_arr = EvalLoopContainer(do_nested_concat=True, padding_index=-100).get_arrays()
	self.assertIsNone(none_arr)

	none_arr = EvalLoopContainer(do_nested_concat=False).get_arrays()
	self.assertIsNone(none_arr)

	# Test one batch
	concat_container = EvalLoopContainer(do_nested_concat=True, padding_index=-100)
	concat_container.add(batch_1)
	arrays = concat_container.get_arrays()
	self.assertIsInstance(arrays, list)
	self.assertEqual(len(arrays), 3)
	self.assertIsInstance(arrays[0], np.ndarray)
	self.assertEqual(arrays[0].shape, (8, 5))
	self.assertIsInstance(arrays[1], dict)
	self.assertIsInstance(arrays[1]["loss"], np.ndarray)
	self.assertEqual(arrays[1]["loss"].shape, ())
	self.assertTrue(np.allclose(arrays[1]["loss"], np.array([1.0])))
	self.assertIsInstance(arrays[2], tuple)
	self.assertEqual(len(arrays[2]), 2)
	self.assertEqual(arrays[2][0].shape, (8, 2, 3))
	self.assertEqual(arrays[2][1].shape, (8, 2))